US7199581B2 - Magnetic resonance measuring system determining the mass of samples in a production line with monitored drift compensation - Google Patents
Magnetic resonance measuring system determining the mass of samples in a production line with monitored drift compensation Download PDFInfo
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- US7199581B2 US7199581B2 US10/836,786 US83678604A US7199581B2 US 7199581 B2 US7199581 B2 US 7199581B2 US 83678604 A US83678604 A US 83678604A US 7199581 B2 US7199581 B2 US 7199581B2
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- G01N24/08—Investigating or analyzing materials by the use of nuclear magnetic resonance, electron paramagnetic resonance or other spin effects by using nuclear magnetic resonance
- G01N24/082—Measurement of solid, liquid or gas content
Definitions
- the invention relates to non-contact check weighing of samples using NMR techniques.
- the nuclei of atoms that have a magnetic moment will have sharply defined frequencies of nuclear oscillation in a strong magnetic field (Larmor frequency).
- the frequency of oscillation of each atomic nucleus will depend on its mass, its dipole moment, the chemical bonding of the atom, the atom's environment (which will be affected by electromagnetic coupling to other atoms in the vicinity), and the strength of the magnetic field seen by the atom.
- the frequency of oscillation will be characteristic, not only of the various atomic species, but also of their molecular environments. By resonantly exciting these oscillations, the atomic species and their environments can be determined with accuracy. This phenomenon is known as “nuclear magnetic resonance,” or NMR.
- a pulse of RF energy is applied at a resonance frequency of atoms of a particular species and environment (e.g. hydrogen atoms in a water environment)
- the atomic nuclei of this type and environment will resonantly be excited, and will later make a transition back to a low state of excitation.
- This transition is accompanied by emission of a radio-frequency signal, at the excitation frequency or a known lower frequency.
- the signal is known as the Free Induction Decay (FID)
- the amplitude and the shape of this FID-curve is related to the amount of nuclei involved in the process and to specific conditions and properties of the atoms in relation to the environment.
- NMR magnetic resonance
- sample nuclear spins align with the field, parallel to the direction of the field.
- the magnetic moments can align themselves either parallel (NSNS) or antiparallel (NNSS) to the static field. Alignment parallel to the static field is the lower energy state and alignment against the field is the higher energy state.
- N + the number of nuclei having spins in the lower energy level
- N ⁇ slightly outnumbers the number in the upper level
- a sample in a static magnetic field will exhibit a magnetization parallel to the static field. Magnetization results from nuclear precession (relaxation) around the static magnetic field.
- the gyromagnetic ratio is related to the magnetic moment of the nucleus under analysis.
- the gyromagnetic ratio of protons is 42.57 MHz/Tesla.
- the frequency thus measured is known as the Larmor frequency, v, which can be conceptualized as the rate of precession of the nucleus in the static magnetic field or the frequency corresponding to the energy at which a transition between the upper and lower states can take place.
- the fundamental NMR signal is derived by inducing transitions between these different alignments.
- Such transitions can be induced by exposing a sample to the magnetic component of an RF (radio frequency) signal, typically generated by an RF coil.
- RF radio frequency
- the magnetic component When the magnetic component is applied perpendicularly to the magnetic field a resonance occurs at a particular RF frequency (identical to the precession frequency, the Larmor frequency), corresponding to the energy emitted or absorbed during a transition between the different alignments.
- RF Radio Frequency
- the signal in NMR spectroscopy results from the difference between the energy absorbed by the spins which make a transition from the lower energy state to the higher energy state, and the energy emitted by the spins which simultaneously make a transition from the higher energy state to the lower energy state.
- the signal is thus proportional to the population difference between the states.
- NMR spectroscopy gains its high level of sensitivity since it is capable of detecting these very small population differences. It is the resonance, or exchange of energy at a specific frequency between the spins and the spectrometer, which gives NMR its sensitivity.
- Pulsed NMR spectroscopy is a technique involving a magnetic burst or pulse, which is designed to excite the nuclei of a particular nuclear species of a sample being measured after the protons of such sample have first been brought into phase in an essentially static magnetic field; in other words the precession is modified by the pulse.
- B o the direction of the static magnetic field
- B o the direction of the static magnetic field
- M o the net magnetization vector lies along the direction of the applied magnetic field B o and is called the equilibrium magnetization M o .
- the Z component of magnetization M Z equals M o .
- M Z is referred to as the longitudinal magnetization.
- M X or M Y transverse magnetization in such a case.
- M 0 In order to properly perform repeated measurements, which is necessary in order to reduce background noise and enhance signal quality, M 0 should be allowed to return to M Z .
- T 1 The spin-lattice relaxation time (T 1 ) is the time to reduce the difference between the longitudinal magnetization (M Z ) and its equilibrium value by a factor of e.
- the net magnetization is rotated into the XY plane by a 90° pulse, it will rotate about the Z-axis at a frequency equal to the frequency of a photon, having the energy corresponding to a transition between the two energy levels of the spin. This frequency is called the Larmor frequency.
- the net magnetization now in the XY plane, starts to dephase because each of the spin packets making it up is experiencing a slightly different magnetic field and hence rotates at its own Larmor frequency. The longer the elapsed time, following the pulse, the greater the phase difference. If the detector coil is sensitive to measurements of fields in the X direction alone, the dephasing results in a decaying signal, eventually approaching zero.
- T 2 The time constant, which describes this decay of the transverse magnetization, M XY , is called the spin-spin relaxation time, T 2 .
- M XY M XY0 e ⁇ t/T2 (5)
- T 2 is always less than or equal to T 1 .
- the net magnetization in the XY plane goes to zero while the longitudinal magnetization grows until M 0 returns to the +Z direction. Any transverse magnetization behaves the same way.
- the spin-spin relaxation time, T 2 is the time to reduce the transverse magnetization by a factor of e.
- the difference between spin-lattice relaxation and spin-spin relaxation is that the former works to return M z to M 0 , while the latter works to return M xy to zero.
- T 1 and T 2 were discussed separately above, for clarity. That is, the magnetization vectors are considered to fill the XY plane completely before growing back up along the Z-axis. Actually, both processes occur simultaneously, with the only restriction being that T 2 is less than or equal to T 1 .
- T 2 star The combined time constant is called “T 2 star” and is given the symbol T 2 *.
- the source of the inhomogeneities can be natural fluctuations in a field, or imperfections in the magnets generating the field or magnetic contaminants, such as iron or other ferromagnetic metals.
- a sample is first placed in a static magnetic field, B o , which is the interrogation zone of the instrument.
- B o a static magnetic field
- a magnetic pulse is applied, which rotates the magnetization vector to a desired extent, typically 90° or 180°.
- a 90° pulse for example, rotates the magnetization vector from the Z-direction into the XY plane resulting in transverse magnetization, M XY , as discussed above.
- FID free induction decay
- NMR magnetic resonance
- the present methods relate to check weighing material contained in a container, which is passing along a product filling line, i.e. production line, by nuclear magnetic resonance (NMR) techniques.
- NMR nuclear magnetic resonance
- the presence of ferrous particles in the measurement volume creates significant degradation of the accuracy of the measurement.
- a continuous, on-line method is provided to determine the presence and impact of these particles. This can be used as an indicator for cleaning activities needed.
- NMR magnetic resonance
- An improvement is provided in a magnetic resonance method for determining the mass of samples in a production line, comprising:
- the comparison of the spin signal and echo signal can comprise calculating the ratio between the spin signal and echo signal, or any other suitable mathematical technique such as integration.
- an improvement is provided in a magnetic resonance method for determining the mass of samples, providing compensation of drift in the magnetic resonance measuring system, comprising:
- a method of determining the presence of metal in samples comprising:
- a method of determining the presence of metal in samples comprising:
- the comparison with like data may relate the signal amplitude of the at least one similar sample to the corresponding output signal amplitude generated by said monitoring step.
- FIG. 1 is a schematic view of a production line with an NMR check weighing station for checking that each container passing through the weighing station has the desired amount of product.
- FIG. 1 a diagrammatically illustrates the form of a check weighing station according to an alternative embodiment in which a magnetic field gradient is applied over an interrogation zone.
- FIG. 1 b diagrammatically illustrates an alternative check weighing station.
- FIG. 1 c illustrates a further check weighing station.
- FIG. 1 d illustrates another check weighing station.
- FIG. 1 e is a schematic plan view of a production line with an NMR check weighing station.
- FIG. 2 is a block diagram of excitation and processing electronics that form part of and control the check weighing station shown in FIG. 1 .
- FIG. 3 is a graph demonstrating the use of spin-echo techniques to indicate the effect of ferrous particles in the system on the NMR sample measurement.
- FIG. 4 a is a schematic diagram of the NMR transmit/receive probe wiring circuit.
- FIG. 4 b is a schematic diagram of one embodiment inserting a stationary sample in the system.
- FIG. 4 c is a schematic diagram of the NMR transmit/receive probe impression.
- FIG. 5 is a graph showing a polarisation curve comparing relative magnetization to time in fractions of T 1 .
- the present methods relate to check weighing material contained in a container, which is passing along a production line, by nuclear magnetic resonance (NMR) techniques.
- check weighing is used by the pharmaceuticals industry for the monitoring and regulation of the amount of a drug in a sealed glass vial during filling.
- the drug weight can be as small as a fraction of a gram, and is required to be weighed with an accuracy of a few percent or better, in a vial weighing tens of grams at a rate of several weighings per second.
- NMR nuclear magnetic resonance
- An NMR apparatus for determining the mass of a sample generally may comprise means for generating a static magnetic field in a first direction through the sample; means for applying an alternating excitation magnetic field in a second different direction through the sample; means for sensing energy emitted by the sample in response to the excitation magnetic field and for outputting a signal in dependence thereon; and means for comparing the signal output by said sensing means with stored calibration data to provide an indication of the mass of the sample.
- Such an apparatus can be used on-line in a product filling line.
- It can provide a non-contacting measure of the mass of the contents of a container independently of the container mass, if the container is made of a material which is not responsive to NMR, and is useful for determining the mass of small quantities of sample such as samples weighing between 0.1 grams and 10 grams which may be contained in glass containers of 20 grams or more, providing an indication of mass and not weight of the sample.
- the apparatus can be used to measure the contents of a container by filling the container with the predetermined amount of sample; transporting each of the filled containers to a weighing station; weighing the sample within each of the containers; sealing the sample within the container; and rejecting any containers which do not contain the predetermined amount of sample within a predetermined tolerance.
- the weighing of the sample includes generating a static magnetic field in a first direction in an interrogation zone for creating a net magnetization within a sample located within the interrogation zone; applying a pulse of alternating magnetic field in a second different direction in the interrogation zone for temporarily changing the net magnetization of the sample located within the interrogation zone; sensing energy emitted by the sample as the net magnetization of the sample returns to its original state and outputting a signal in dependence thereon; and comparing the signal output by the sensing step with calibration data which relates the mass of at least one similar sample of known mass to the corresponding signal output by the sensing step, to provide the indication of the mass of the sample within each container.
- such an apparatus and method can be used in a variety of applications, including but not limited to cosmetics, perfumes, industrial chemicals, biological samples and food products. It can measure high value products where 100% sampling can reduce wastage, and can be used to determine the mass of samples that are in solid form, in powder form, in liquid form and in gas form, or any combination thereof.
- FIG. 1 shows a portion of a production line, which fills glass vials 1 with a drug sample. Included is a weighing station 3 that is provided “in-line” for weighing each of the filled non-continuous and discrete samples in vials that pass therethrough, and a reject station 5 that removes those vials from the line that do not have the sufficient amount of the drug to meet product specifications.
- the vials 1 are transported to the weighing station 3 from a filling (and optionally sealing) station (not shown) by a conveyor belt 7 which, as represented by the arrow 9 , moves in the z direction through the action of rotating conveyor wheels 11 .
- the weighing station uses NMR techniques of measurement to determine the mass of the drug sample within each of the glass vials 1 .
- the weighing station 3 comprises a permanent magnet 13 , an RF coil 15 and a computer control system 17 .
- the magnet 13 is creates a homogeneous direct current (DC) or static magnetic field in the x direction across the conveyor belt 7 .
- the sample in the glass vial contains nuclei which each possess a magnetic moment, e.g. 1H nuclei (protons). This magnetic moment, discussed above, is a result of the spin of the nuclei.
- the static magnetic field strength is such that the Larmor frequency of the sample is in the radio frequency range of the electromagnetic spectrum.
- Applying an alternating current (AC) magnetic field to the sample at the sample's Larmor frequency and orientated orthogonal to the static magnetic field will cause the sample's net magnetization to rotate about the AC magnetic field's axis, away from the direction of the static field.
- this magnetic field is generated by applying a corresponding AC current to the RF coil 15 .
- the angle of rotation of the net magnetization can be varied by varying the amount of energy delivered to the RF coil 15 .
- an excitation field that causes a 90° rotation is used to excite the sample.
- the sample After the 90° pulse has been applied to the sample, the sample is left in a high-energy, non-equilibrium state, from which it will relax back to its equilibrium state.
- electromagnetic energy at the Larmor frequency is emitted, the magnetic component of which induces current in the RF coil 15 , the peak amplitude of which varies with, among other things, the number of magnetic moments in the sample and hence the number of molecules in the sample.
- the received signal is then passed to the computer control system 17 , which compares the peak amplitude of the signal received from the unknown sample, with the peak amplitude of a signal received from a calibration sample with a known mass (or weight), to determine the mass (or weight) of the sample being tested.
- the check weighing station 3 may be able to generate and receive signals at different Larmor frequencies needed to be able to excite different NMR responsive elements in samples. If the computer control system 17 can store calibration data for each of the different samples, then the check weighing station would be able to determine the mass of various samples using the NMR signals from the different NMR responsive elements.
- the control system comprises a connection terminal 21 for connecting the control system to the RF coil 15 .
- the connection terminal 21 is connectable, through switch 23 , to a signal generator 25 and a power amplifier 27 which are operable to generate and amplify respectively the excitation signal which is applied to the RF coil 15 .
- the connection terminal 21 is also connectable, through the switch 23 , to a receiving amplifier 31 which amplifies the signal received from the sample under test.
- This amplified signal is then filtered by the filter 33 to remove noise components and then passed to the mixer 35 where the received signal is down converted to an intermediate frequency (IF) by multiplying it with an appropriate mixing signal generated by the signal generator 25 .
- the IF signal output by the mixer 35 is then filtered by the filter 37 to remove the unwanted components generated by the mixer 35 .
- the filtered IF signal is then converted into a corresponding digital signal by the A/D converter 39 and is then passed to the microprocessor 41 .
- the microprocessor 41 controls the operation of the signal generator 25 and the switch 23 .
- the microprocessor 41 may operate to ensure that the signal generator 25 generates the excitation signal when the filled vial 1 is at the desired location within the check weighing station 3 .
- the microprocessor 41 knows when the vial 1 is at the correct location from a signal received from the position sensor electronics 47 which is connected, through connection terminal 49 , to an optical position sensor 50 mounted in the check weighing station 3 . Referring to FIG. 1 , when the glass vial 1 passes by the optical position sensor 50 , a light beam 52 is broken. This is detected by the position sensor electronics 47 which in turn signals the microprocessor 41 . Based on this information and the speed of the conveyor belt 7 (provided by the conveyor controller 51 ), the microprocessor determines the appropriate timing for the application of the burst of excitation current and signals the signal generator 25 accordingly.
- the net magnetisation and thus the strength of the resultant signal produced by a sample varies with time in the static magnetic field.
- the longitudinal relaxation time depends upon the sample being tested and the strength of the static magnetic field. Therefore, given the strength of the static magnetic field and the type of sample which is being tested, the relaxation time can be determined. This information, combined with the speed of the conveyor belt 7 , determines the minimum length of the magnet 13 in the Z-direction which is required to ensure that as large a signal as possible is generated by the sample under test.
- a capacitor (not shown) is connected across the ends of the RF coil 15 so that it is tuned to the Larmor frequency of the sample.
- the Larmor frequency of an MR responsive element such as hydrogen is calculated by multiplying the static magnet's DC magnetic field strength by the gyromagnetic ratio for the element (which for hydrogen is 42.57 MHz/Tesla).
- the gyromagnetic ratio for other MR responsive elements can be found in CRC Handbook of Chemistry & Physics, published by CRC Press Inc.
- the Larmor frequency of an MR responsive element such as hydrogen is calculated by multiplying the static magnet's DC magnetic field strength by the gyromagnetic ratio for the element (which for hydrogen is 42.57 MHz/Tesla).
- the gyromagnetic ratio for other MR responsive elements can be found in CRC Handbook of Chemistry & Physics, published by CRC Press Inc.
- the tuning of the RF coil 15 in this way makes the system less susceptible to electromagnetic interference or to other MR signals from nuclei with different gyromagnetic ratios.
- the excitation current flowing through the RF coil 15 generates a corresponding magnetic field in the Z-direction. This excitation magnetic field causes the net magnetisation of the sample in the vial 1 to rotate or precess about the Z-axis at the Larmor frequency.
- the excitation current is removed from the RF coil 15 , the nuclei in the sample begin to relax back to their equilibrium positions, emitting RF energy at the Larmor frequency as they do so. This induces a signal in the RF coil 15 which is seen to decay exponentially and is referred to as the transverse relaxation time. This depends upon the sample being tested and not on the static field strength.
- the peak amplitude of the induced signal is at its maximum shortly after the excitation current stops, after which point the signal decays to zero.
- the amplitude of the signal induced in the RF coil 15 by the sample is directly proportional to the number of magnetic moments in the sample. Consequently, in this embodiment, the microprocessor 41 monitors the peak signal level which it receives from the A/D converter 39 after the excitation signal has been removed from the RF coil 15 .
- the microprocessor can determine the average signal over a period of time or fit the shape of the curve in order to improve accuracy.
- the microprocessor 41 compares this peak signal level with calibration data obtained by testing a similar sample or samples of known mass, to provide an indication of the mass of the sample currently being tested.
- this calibration data is obtained from a number of similar samples of different known masses during a calibration routine before the production batch is begun and is stored in memory 53 .
- the calibration data is a function which relates the peak amplitude of the MR signal received from the sample under test to the mass of the sample.
- the RF probe monitors the energy emitted by the sample as the net magnetisation of the sample returns to its original state of equilibrium, and generates an output signal having a characteristic that is proportional to the energy emitted, such as current amplitude.
- the computer control system receives the RF probe output signal.
- a processor compares the current amplitude or other output signal characteristic with corresponding data obtained from at least one similar sample of known mass, and determines the mass of the sample from die results of the comparison. It is to be understood that although for purposes of illustration the embodiment has been described as measuring the peak amplitude of the induced signal, any chemometric characterization technique can be used that derives a single value from the energy emitted and the output signal generated.
- comparison techniques may include comparing the FID characteristics of the sample with like FID characteristics of at least one known sample, i.e., the calibration data.
- the microprocessor 41 determines that the mass of the current sample being analysed is not of the required mass within a given tolerance, it outputs a control signal on control line 55 to the reject controller 57 .
- the reject controller then outputs a signal to output terminal 59 which is connected to the reject station 5 , for causing the reject station to remove the current vial 1 being tested from the conveyor belt 7 when it arrives at the reject station 5 .
- the computer control system 17 may also comprise a user interface 61 for allowing the user to program into the control system 17 what the correct mass of each sample should be for a given batch of product.
- a single measurement of a sample's mass is determined for each vial.
- the accuracy of the measurement can be improved by taking an average of repeated measurements.
- the rate at which measurements can be made on the same sample is determined by the relaxation time discussed above. In particular, after the excitation signal has been removed, it takes approximately 3 times the relaxation time for the protons to return to their original aligned state in the static magnetic field, at which point a further burst of excitation current can be applied.
- Separate measurements could be obtained either by using a number of different RF coils spatially separated along the Z-direction.
- the conveyor belt could be stopped each time a vial reaches the interrogation area and multiple measurements made.
- the interrogation zone of the magnet and RF coil is large enough to allow multiple measurements to be taken considering the speed of the conveyor belt.
- the accuracy of the system will depend upon the homogeneity of the RF coil and the magnetic field within the interrogation zone as well as on the system signal to noise and the RF coil's fill factor. If the field patterns of the magnet and RF coil are known in advance, then this knowledge can be used to make corrections on the different measurement signals. Also, additional X, Y and Z coils (known in the art as shims) may also be provided to improve the homogeneity of the static magnetic field.
- FIG. 1 a diagrammatically illustrates another embodiment in which the components of a check weighing station 3 allow multiple vials to be located within the RF coil 15 interrogation zone at the same time and which allow a mass measurement to be made of the sample within each vial individually.
- a separate pair of coils 71 and 73 are located either side of the conveyor belt 7 , which operate to provide a magnetic field gradient across the conveyor belt 7 .
- each vial can be interrogated separately by applying three different narrow band RF pulses at the appropriate Larmor frequency.
- a broad band RF pulse could be applied over the interrogation zone and the resulting MR signals from the samples can be resolved by taking the Fourier transform of the received signal after the excitation pulse has ended, as is standard practice in MR imaging.
- the gradient coils are arranged to apply a gradient in the same direction as the static magnetic field which is generated by the magnet 13 .
- gradient coils can be arranged to provide magnetic field gradients in one or more of the X, Y or Z axes so that the entire volume of the interrogation zone can be spatially resolved.
- FIG. 1 b illustrates an embodiment where the two gradient coils 71 and 73 are provided at opposite ends of the RF coil's interrogation zone.
- the RF coil 15 comprises three separate portions 15 a , 15 b and 15 c .
- each of the samples can be interrogated separately or simultaneously in the same way as in the embodiment described with reference to FIG. 1 a .
- B refers to the magnetic field strength of the static magnetic field generated by magnet 13 .
- N and S refer to the north and south direction of the magnetic field respectively.
- a plurality of samples were located within the interrogation zone and either interrogated separately or simultaneously.
- each of these samples will experience a slightly different magnetic field and will be in a different position relative to the RF coil, separate calibration data can be used for each of the sensing positions in order to try to reduce errors caused by inhomogeneities in the static magnetic field or in the RF coil.
- the RF coil generated a magnetic field in the Z-direction along the direction of movement of the conveyor belt 7 .
- the RF coil can be located at any angle relative to the DC magnetic field, provided the field which it generates is relatively homogenous over the sample being tested and provided it comprises a component which is orthogonal to the static magnetic field.
- FIG. 1 c diagrammatically illustrates an embodiment where three separate RF coils 15 d , 15 e and 15 f are provided under the conveyor belt 7 , each of which is operable to generate an AC magnetic field in the Y-direction. This embodiment allows the samples in three vials to be tested simultaneously. It also allows the system to interrogate the sample in each vial three times, once by each of the RF coils.
- a permanent magnet was used to generate the static magnetic field.
- electromagnets, current carrying coils or superconducting magnets could be used in place of the permanent magnet to generate the necessary DC magnetic field.
- the DC magnetic field was applied across the conveyor belt in the X-direction.
- the DC magnetic field can be applied through the sample in any direction.
- the north and south pole of the magnet may be placed above and below the conveyor with the RF coil being, for example, in the same orientation as in the first embodiment.
- 1 d shows yet another embodiment in which a solenoid coil 75 is wound along a length of the conveyor belt 7 for generating the static magnetic field along the length of the conveyor belt 7 , i.e. in the Z-direction.
- the RF coil 15 is provided at one side of the conveyor 7 and a separate detector coil 77 is provided at the opposite side of the conveyor 7 .
- FIG. 1 e shows a schematic plan view of a production line with an NMR check weighing station.
- the check weighing station 100 includes an in-feed section 101 comprising a conveyor belt or other transport mechanism, the check weighing section 102 containing the magnet, RF antenna and in part defining the interrogation zone 103 , a reject section 104 leading to a reject buffer 105 , and an out-feed section 106 .
- the check weighing station may contain an operator panel 107 .
- a method is provided to determine independently the degradation of the NMR measuring system due to the accumulation of ferrous particles.
- One embodiment includes a method for the determination of ferrous particles inside packages or containers without destructive testing and without disrupting the movement of the production line.
- Ferrous particles disrupt the homogeneity of a magnetic field.
- the consequence is that the FID (Free Induction Decay) of the pulsed NMR measurement is steeper than it would be in the perfectly homogeneous case.
- FID Free Induction Decay
- By applying a specific spin-echo experiment (measurement) it is possible to determine the ‘true’ decay. Comparing the original decay with the ‘true’ decay shows that the more particles are included in the volume, the more prominent the differences in decay are. After calibration with known samples, this method can be used to measure the content of ferrous particles.
- the same method can also be applied to determine the quality of the conveyor system. It is possible that over time, metal (ferrous) particles adhere to the belt. Above a certain level, the decay is too fast and actually disturbs the quality of the weight measurement. Using the spin-echo sequence regularly allows the system to perform a self-check, and to issue an alarm when cleaning of the system is required.
- the nuclei of hydrogen When a 90° excitation pulse is applied to a magnetized sample, the nuclei of hydrogen respond by emitting a decaying signal of the same frequency as the excitation signal. This is called the Free Induction Decay (FID).
- FID Free Induction Decay
- This decay has several origins, including: the fact that the resulting magnetic moment gets realigned again with the main stationary field, and the fact that the precessing magnetic moments of the contributing nuclei get out of phase.
- the FID is determined by a couple of factors, of which the homogeneity of the main magnet field and the spin-spin relaxation (T 2 ) are the most prominent.
- the amplitude of the ‘echo’ in the spin-echo experiment relates to the ‘true’ FID related to the T 2 . Comparing the echo amplitude with the original FID provides information about the homogeneity of the main magnet field. This homogeneity is largely deteriorated by ferrous particles close to the product. Therefore this abovementioned comparison gives information about the amount of ferrous particles.
- This comparison can contain any possible mathematical technique using simple ratios or integrating steps.
- FIG. 3 This technique is demonstrated graphically in FIG. 3 , wherein S 1 /E is a larger quantity than S 2 /E.
- amplitude is shown at a time after the 90° pulse 110 , at the measurement time 111 , and at the echo signal time 112 , where the clean signal 113 is S 1 , the “contaminated” signal 114 is S 2 , and the echo signal 115 is E.
- the vial speed was varied between 200 and 570 vials per minute. The method as such, however, is not velocity dependent.
- the system can be adapted such that when the ratio falls below a predetermined value, an alarm will be issued indicating that the belt needs to be cleaned.
- metal particles as such may not directly influence the magnet field, but would introduce effects on the detection of the FID. This might be detected by applying pulse sequences other than spin-echo that are useful in other fields of NMR.
- the system includes a permanent magnet creating a magnetic field of roughly 0.17 T in the center of the volume. Between the poles of the magnet, the coil structure is fitted. This coil acts as a sender and receiver of electromagnetic radiation.
- the coil structure design may be specially adapted to minimize airflow disturbance.
- the NMR measurement is nondestructive and measurement taking is fast enough to enable 100% protocolling. Further, the system is not influenced by airflows of the surrounding environment. However, due to electronic drift effects, temperature variations and other effects, it is conceivable that the signal amplitude may drift as well. To prevent this a periodic verification with a standard is necessary.
- Certain embodiments of the method are directed to avoiding this regular standardization step, by fitting a so-called ‘golden sample’ inside the measurement system, at least semi-permanently. There are various ways to determine the right sample.
- the constant stability sample can be one of the following.
- the permanent compensation of potential drifts in the NMR measuring system is a major improvement of the functionality of the system, and additionally provides support for validation processes. Further, it facilitates the application of the NMR measuring system in isolators, useful in high purity systems.
- FIGS. 4 a , 4 b and 4 c are schematic diagrams of the NMR transmit/receive probe and one embodiment inserting a stationary sample in the system.
- FIG. 4 a shows a schematic of the electrical wiring circuit 120 of the transmit/receive probe.
- the wiring is such that when an alternating current is induced a varying magnetic field is created in a direction perpendicular to the main magnetic field and in the direction of the transport mechanism.
- FIG. 4 b shows that inside the transmit/receive coil 130 , a stationary sample 131 is positioned.
- the transmit/receive coil 130 may comprise RF conductor 132 and optionally a Faraday cage 133 at least partially enclosed within cladding 134 .
- a glass vial 1 is shown in the center of the outside of the transmit/receiver coil 130 .
- FIG. 4 c shows one embodiment of a layout of the transmit/receive coil 140 .
- the NMR equipment includes a permanent magnet having a bore-size that allows a transportation means for the products that are measured to pass through an interrogation zone. Inside the magnet, a specific probe acts as a radio-frequency electromagnetic emitter/receiver that both excites the product material and receives the response.
- the probe construction is such that there is maximum allowance for transportation means to carry the products through the system. It is important to discriminate between products that do give rise to NMR signals and those that do not, such as glass, polyvinyl chloride (PVC), and polytertrafluoroethylene (PTFE).
- the measurement probe will be equipped with a stationary sample of a piece of material that generates a stable NMR signal.
- the presence of a very minimal amount of metal particles inside the measurement volume will cause a severe degradation of the NMR signal amplitude.
- the amount of distortion can be measured and will serve to determine the actual amount of mercury present in the product passing through the interrogation zone.
- the method involves implementation of a stationary sample inside of the magnet/antenna as discussed in further detail above.
- the embodiment may include transport means adapted for moving the light sources in and out of the system.
- the associated magnetic moments are aligned to the external magnetic field lines.
- the alignment is not perfect; the vectors actually precess around the field lines.
- the precession frequency, the Larmor frequency is linearly proportional to the external field strength and is therefore known.
- the transmit pulse is switched off, the magnetic moments return to the original situation while emitting a signal with the Larmor frequency. This decaying signal can be detected with the same antenna as the signal has been emitted originally, just by switching the electronic circuit by known means.
- the method is applicable for other situations where metals need to be detected in a non-destructive, non-contact way with high precision.
- NMR magnetic resonance
- the amplitude of the Free Induction Decay (FID) signal is linearly proportional to the amount of product, the shape of the FID is also dependent on some external conditions. Local magnetic field inhomogeneity may cause the FID to decline much faster. Ferrous particles cause local inhomogeneity and decrease the FID and the detected signal. The influence is related to the size of those particles, since the influence is related to interference with the NMR probe antenna.
- NMR measurements were applied to a number of visually determined contaminated product samples and a number of clean samples to determine the FID signals of the various samples.
- the signal to noise ratio can be improved by focusing the NMR probe on the cake volume itself and by applying a higher magnet field, the NMR system was able to discriminate between the contaminated and clean samples by detecting an FID signal difference on the order of 20%.
- the experimental system did not discriminate between loss of signal due to metal particles and a low level of content, it is unlikely that a signal difference of 20% would be due to a difference in content weight of 20%. The system is therefore useful in indicating metal contamination of product samples, even if contamination is present in the interior of the freeze-dried cake, as the resulting signal for the contaminated samples were lower than expected.
- the NMR apparatus includes a permanent magnet with a bore-size that allows a transportation means for the products that are measured to pass through an interrogation zone.
- a specific probe may act inside the magnet as a radio-frequency electromagnetic emitter/receiver that both excites the product material and receives the response.
- the probe construction is such that there is maximum allowance for transportation mechanisms to carry products through the system.
- the measurement probe will be equipped with a stationary sample, a piece of material that generates a stable NMR signal. The presence of a very minimal amount of metal particles inside the measurement volume will cause a severe degradation of the NMR signal amplitude.
- the sample In the application of NMR techniques to determine characteristics of the contents of containers, such as vials, in a non-stationary manner, prior to the sample being in the measurement position the sample is moving through the magnetic field and is therefore being pre-magnetised (or pre-polarised).
- the sample may be excited with an excitation pulse, for example a 90° pulse. This pulse causes the spins of the protons to precess in a plane, perpendicular to the main magnetic field.
- the relaxation process is dominated by dephasing of the spin precessions of the individual protons, and this free induction decay (FID) signal is measured.
- the amplitude of this signal is linearly proportional to the amount of protons in the sample, and therefore a sample calibration allows the method to be used as a measurement method, such as for weighing.
- the process of polarization is a process with a typical time-constant, the T 1 (spin-lattice constant).
- T 1 spin-lattice constant
- NMR measurements can be taken when the pre-magnetization is complete. This stage is reached when taking approximately 5 times T 1 as a magnetization period.
- the T 1 is of the order of 1 second.
- a pre-magnetization step of 5 seconds would be necessary.
- the measurement is applied to incompletely magnetised samples and this measurement is accurate enough if the history (in terms of exposure to the magnetisation field) of every subsequent sample is identical, for example: the T 1 influencing factors are known (via specific calibration) and can be incorporated into the measurement calculations (for example, temperature), and the speed of every subsequent sample does not vary, or is accurately known and can be compensated for.
- the graph of FIG. 5 shows a magnetisation curve and the consequence of having typically only half of a T 1 available for magnetisation, yielding only 39% of magnetisation.
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Abstract
Description
N − /N +=exp(−E/kT), (1)
where E is the energy difference between the spin states; k is Boltzmann's constant, 1.3805×10−23 J/Kelvin; and T is the temperature in Kelvin. As the temperature decreases, so does the ratio N−/N+. As the temperature increases, the ratio approaches unity.
v=γB, (2)
where B is the magnetic field strength and Gamma is the gyromagnetic ratio of at least one atom, typically hydrogen, in the sample material. The gyromagnetic ratio is related to the magnetic moment of the nucleus under analysis. The gyromagnetic ratio of protons is 42.57 MHz/Tesla. The frequency thus measured is known as the Larmor frequency, v, which can be conceptualized as the rate of precession of the nucleus in the static magnetic field or the frequency corresponding to the energy at which a transition between the upper and lower states can take place.
M Z =M 0(1−e −t/T1) (3)
T1 is therefore defined as the time required to change the Z component of magnetization by a factor of e. Hence, at t=T1, MZ=0.63 M0. In order to properly perform repeated measurements, which is necessary in order to reduce background noise and enhance signal quality, M0 should be allowed to return to MZ. In other words, the longitudinal magnetization MZ, which equals zero upon saturation, should be allowed to fully return to the +Z direction and attain its equilibrium value of M0. While this theoretically would take forever, (i.e., following saturation, MZ=M0 when t=∞), it is generally considered sufficient when MZ=0.99 M0, which occurs when t=5T1. This places time constraints on the speed at which a sample may be measured multiple times or the overall throughput of samples through an interrogation zone.
M z =M o(1−2e −t/T1) (4)
The spin-lattice relaxation time (T1) is the time to reduce the difference between the longitudinal magnetization (MZ) and its equilibrium value by a factor of e. Here, too, an elapsed time of t=5 T1 is required in order for MZ to return to a value of 0.99 MO, placing a similar time constraint on sample throughput.
MXY=MXY0 e−t/T2 (5)
T2 is always less than or equal to T1. The net magnetization in the XY plane goes to zero while the longitudinal magnetization grows until M0 returns to the +Z direction. Any transverse magnetization behaves the same way.
1/T 2*=1/T 2+1/T 2inh. (6)
The source of the inhomogeneities can be natural fluctuations in a field, or imperfections in the magnets generating the field or magnetic contaminants, such as iron or other ferromagnetic metals.
Claims (7)
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US10/836,786 US7199581B2 (en) | 2003-05-16 | 2004-04-30 | Magnetic resonance measuring system determining the mass of samples in a production line with monitored drift compensation |
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US10/836,786 US7199581B2 (en) | 2003-05-16 | 2004-04-30 | Magnetic resonance measuring system determining the mass of samples in a production line with monitored drift compensation |
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EP (1) | EP1625571A4 (en) |
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EP1625571A2 (en) | 2006-02-15 |
CN1788214A (en) | 2006-06-14 |
KR20060020631A (en) | 2006-03-06 |
JP2006529026A (en) | 2006-12-28 |
US20050116712A1 (en) | 2005-06-02 |
WO2004104989A3 (en) | 2005-03-31 |
WO2004104989A2 (en) | 2004-12-02 |
EP1625571A4 (en) | 2008-01-09 |
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